An Energetic Analysis of Rhomboidal Linkage Robots for Hopping Lunar Exploration

2021 Second International Symposium on Instrumentation, Control, Artificial Intelligence, and Robotics (ICA-SYMP) Pub Date : 2021-01-20 DOI:10.1109/ICA-SYMP50206.2021.9358244

J. Lo, B. Parslew

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引用次数: 3

Abstract

In this paper, we present a conceptional design framework for jumping robots for lunar exploration. A method is developed for spring placement and sizing that maximises the onboard elastic potential energy storage, which is essential for space missions. In the class of rhomboidal linkage robots, the analysis shows that torsion springs placed at the knee joints store more energy than the commonly used extension or linear compression springs for a given charging-actuator force; torsion springs store around 80% of the idealized maximum attainable elastic energy storage, compared to only 60% for an extension spring. A physical demonstrator is developed using torsion springs, and exhibits repeatable jumps with an average jump height of 1.1m under earth gravity, equivalent to 6.7m under lunar gravity. However, preliminary trials show the choice of substrate is shown to influence the jump height. This effect is predicted to be pronounced when jumping from lunar regolith.

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跳跃月球探测菱形连杆机器人的能量分析

本文提出了一种用于月球探测的跳跃机器人的概念设计框架。开发了一种使机载弹性势能存储最大化的弹簧放置和尺寸的方法，这对空间任务至关重要。在菱形连杆机器人中，分析表明，对于给定的充电驱动器力，放置在膝关节处的扭转弹簧比常用的拉伸弹簧或线性压缩弹簧储存更多的能量;扭转弹簧储存了理想最大弹性能量的80%左右，而延伸弹簧只有60%。利用扭簧技术研制了物理演示器，实现了可重复跳跃，在地球重力下平均跳跃高度为1.1米，在月球重力下相当于6.7米。然而，初步试验表明，衬底的选择会影响跳跃高度。据预测，从月球风化层跳下时，这种效应会很明显。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 Second International Symposium on Instrumentation, Control, Artificial Intelligence, and Robotics (ICA-SYMP)

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